1 Answer
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In Schmidt & Dilcher 2007, the authors were interested specifically on how amber can trap aquatic organism, so this is a specific, out-of-the-norm case study but it might give you at least on order of magnitude. Here is an extract:

Within the first day or two after initial contact with water, all
three resin fractions were traps for limnetic organisms. The resinous
film at the surface then dried out and broke into small
centimeter-sized fragments, so no long-term preservation can be
expected for this exudate. The pieces of resin hanging at the water
surface became more and more solid within a few days because of air
contact at their upper surface. After 1 week, these pieces were nearly
solidified (Fig. 1 D).

And later:

In contrast, the large resin bodies on the ground did not solidify as
long as they were covered with water. But this resin was also
initially a trap for microorganisms before a thin hardened skin
developed at the resin surface after 1 or 2 days in the water, which
prevented tiny organisms from getting stuck. Nonetheless, the resin
remained liquid inside, and therefore large arthropods that were able
to break through this skin could become entrapped over a couple of
weeks. [...] The resin solidified when exposed to the air in the
laboratory or by decreasing water level in the swamp during the
summer.

So the polymerization process to go from resin to solidified resin (copal) takes weeks. At that point, the system is already closed meaning the contained organisms correspond to that time interval.

The next step (amberification) consists of further polymerization as well as oxydation and can take several million years (Poinar 1992). However the minimum time needed for this process is unknown.